I have developed a server and client application for streaming video frames from one end to another using RTSP. Now, in order to gather statistics which will assist me in improving my applications, I need to measure the elapsed time between sending the frame and receiving the frame.

At the moment I am using the following formula:

Client_Receive_Timestamp - Server_Send_Timestamp = Elapsed_Time


It seems to me that the elapsed time is about 100-200ms too high. I think the reason is that the server clock and client clock are not in sync and have a difference of about 100-200ms.


How can I accurately measure the elapsed time between the two mashines?

The topic Accurately measuring elapsed time between machines suggests calculating a round-trip delay. However, I can't use this solution as the client doesn't request the frames. It simply receives frames via RTSP.

  • Could you clarify why you can't calculate a round-trip delay? Are you forced to use the RTSP stream as your only network connection? If not, you could use simple pings over a different network connection to estimate the round-trip time. – Lukas Boersma Sep 19 '15 at 11:01
  • Use third machine and confirm your doubts. – lsalamon Sep 19 '15 at 11:38
  • @LukasBoersma My goal is to measure how long it takes to deliver the frame, not to measure how long it takes to send and receive a single packet. – chrisp Sep 19 '15 at 12:42
  • 1
    You send the current time to the second machine. When you receive it there, add half of the round-trip time to estimate the current time on the sending machine. Do it multiple times and take the median to reduce noise. For details, look at the NTP protocol, which does basically that. – Lukas Boersma Sep 19 '15 at 12:54
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    Note that RTSP (RFC2326) is a protocol for establishing and controlling media sessions between end points - not for transporting the media stream itself. The media stream is often (but is not required to be) transported using the RTP transport protocol (RFC3550), whose companion control protocol RTCP (in the same RFC) specifies (among other things) means of reporting transit delays to the origin endpoint, taking into account issues like scalability. Well worth a look. – Jeremy Sep 21 '15 at 8:00


then you can simply subtract the "sent timestamp" from the "received timestamp" to obtain the latency duration. The observed error will be less than the sum of both clock errors. If the time scales are small enough (probably anything smaller than an hour) you can reasonably ignore slew effects.

If ntpd is not already running on both machines, and if you have the necessary permissions, then you can

$ sudo ntpdate -v pool.ntp.org

to force a synchronization with the pool of publicly-available time servers.

Then you can use the c++11 high_resolution_clock to calculate the duration:

/* hrc.cc */
#include <chrono>
#include <iostream>

int main(int,char**){
  using std::chrono::high_resolution_clock;
  // send something                                                                                                                      
  high_resolution_clock::time_point start = high_resolution_clock::now();
  std::cout << "time this" << std::endl ;
  // receive something                                                                                                                   
  high_resolution_clock::time_point stop = high_resolution_clock::now();
    << "duration == "
    << std::chrono::duration_cast<std::chrono::nanoseconds>(stop-start).count()
    << "ns"
    << std::endl
  return 0;

Here's what the previous example looks like on my system:

$ make hrc && ./hrc
c++     hrc.cc   -o hrc
time this
duration == 32010ns

I need to measure the elapsed time between sending the frame and receiving the frame.

You don't need precise timestamps for this. You can average the estimated latency.

If A sends the packet (or a frame) to B, B responds immediately(*):

A(sendTime) ---> B ---> A(receivedTime)

then you can calculate the latency easily:

latency = (receivedTime - sendTime) / 2

This assumes of course that the latency is symmetrical. You can find more elaborate algorithms if you research "network latency estimation algorithm" phrases.

Having the estimated latency you can of course estimate time difference (but it doesn't seem necessary):

A(sendTime) ---> B(receivedTimeB) --(receivedTimeB)--> A

timeDelta = sendTime + latency - receivedTimeB

Note that even if you average many results, this algorithm is probably highly biased. This is just posted as a simple example to the general idea.

(*) The fact that it does not happen really immediately induces an error of course. This depends on how heavily machine B is loaded.

  • The problem here is that I can't just respond with a single packet. I would need to respond by sending the entire frame back to the server because it takes longer to transport an entire frame (= multiple packets). – chrisp Sep 19 '15 at 12:45
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    @Chris. The "ping" packet is irrelevant here. If you can make B respond at once, it doesn't matter what are you sending. You can make exactly the same calculations using frames. So you can perform the measurements online, while transmitting data. Or, if you need to do that before the transmission occurs, you can use N differently sized packets and estimate how fast the latency grows with the size of the packet. This would allow you to estimate the latency of an arbitrary frame size. – BartoszKP Sep 19 '15 at 12:55
  • Sounds like a good idea. However, the solution mentioned in the comments below the question seems easier to implement. – chrisp Sep 19 '15 at 13:01
  • @Chris. The solution in comments assumes you know the round-trip time. So it's identical to the solution I've posted at the end of my post (estimating timeDelta). Sending sendTime is the same as sending "current time". – BartoszKP Sep 19 '15 at 13:06

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